Mechanism for remotely controlling equipment

ABSTRACT

The present invention provides a system and method for wirelessly controlling a water jet machine by way of a wireless connection between the water jet machine and a computing device. The computing device provides an interface for controlling the operating device either directly to the water jet machine or via a control unit which is removably connected to the water jet machine. The water jet machine or control unit communicates wirelessly with the computing device, allowing a user to move about freely while still controlling the water jet machine. The control unit may include at least one valve for use in controlling the operating device.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No.14/204,451, filed Mar. 11, 2014, which claims priority from U.S.Provisional Application Ser. No. 61/821,433, filed May 9, 2013, theentire disclosures of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Technical Field

The present invention relates to control of devices. More particularly,the present invention relates to providing wireless control capabilitiesto an operating device. Specifically, the present invention relates toproviding wireless control of a machine through a computing deviceconnected wirelessly to the machine.

2. Background Information

Often operating devices commonly used in industry are both manuallycontrolled by a user as well as dangerous to the user. A water jetcutting machine is an example of such an operating device. Water jetcutting is an extremely dangerous activity, as the pressurized stream ofwater can cut through materials as hard as metal. It follows that anypart of a human would easily be cut by this stream of water. Therefore,a user must always keep proper control of the cutting machine and ensurethat the user's extremities are out of harm's way. However, water jetcutting machines are controlled via hydraulic or pneumatic tubes runningfrom a control station which the user actuates to control the water jetcutting machine. This control station is typically a desk-like structurewith four extending legs and is generally not practically movable.Therefore, the user is in a fixed position which may force the user totake unnecessary risks to remain in the fixed position while the waterjet cutting machine passes close thereby. Further, the immovable natureof the control station may severely limit the user's ability to view theactual operations of the cutting machine. Still further, current waterjet cutting machines do not account for whether the user is actually incontrol of the machine. The machine simply keeps cutting and performingits operations whether or not the user is positioned at the controls.

Thus, there is a tremendous need in the art to provide a mechanism forthe user or controller of an operating device such as a water jetcutting machine to remain in control of the machine while stillremaining mobile and not fixed to a particular position. Further, thereis an additional tremendous need in the art to provide a system ormethod for ensuring the user is in control of the operating device, andhas not become incapacitated, disabled, or simply left the machine'scontrols. There is a need in the art for an easy to assemble solution,possibly by way of a downloadable application installed on a computingdevice and connected logically to portions of the computing device'shardware.

SUMMARY

In one aspect, the invention may provide a system comprising: acomputing device, wherein the computing device includes a first wirelessmodule; a fluid jet machine, wherein the fluid jet machine includes apump unit, a nozzle, and an operation; a second wireless module, whereinthe second wireless module is connected to the fluid jet machine; awireless communications link between the computing device and the fluidjet machine, wherein the wireless communication link is formed by thefirst wireless module and the second wireless module; a signal, whereinthe signal is generated by the computing device and communicated to thefluid jet machine by way of the wireless communications link; andwherein the operation is actuated when the fluid jet machine receivesthe signal.

In another aspect, the invention may provide a method comprising thesteps of: forming a wireless communication link between a portablecomputing device and a fluid jet machine; sending a first signal fromthe computing device to the fluid jet machine via the wirelesscommunication link; and actuating an operation of the fluid jet machineupon receiving the first signal.

In another aspect, the invention may provide a method comprising thesteps of: forming a wireless communication link between a portablecomputing device and a control unit; forming a wired communication linkbetween the control unit and a fluid jet machine; sending a first signalfrom the computing device to the control unit via the wirelesscommunication link; translating the first signal into a second signal;sending the second signal from the control unit to the fluid jet machinevia the wired communications link; and actuating an operation of thefluid jet machine upon receiving the second signal.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

A sample embodiment of the invention, illustrative of the best mode inwhich Applicant contemplates applying the principles, is set forth inthe following description, is shown in the drawings and is particularlyand distinctly pointed out and set forth in the appended claims.

FIG. 1 is a view of a first embodiment of the present invention,including an operating device in the form of a water jet cutting machineand a computing device in the form of a remote control;

FIG. 2 is an enlarged view of an embodiment of the remote control of thepresent invention;

FIG. 3 is a view of a prior art water jet cutting system juxtaposed witha portion of a second embodiment of the present invention;

FIG. 4 is a view of a portion of the second embodiment of the presentinvention, including a computing device and a control unit;

FIG. 5 is a perspective view of a prior art control station next to anoperating device in the form of a water jet cutting machine; and

FIG. 6 is a perspective view of the second embodiment of the presentinvention next to an operating device in the form of a water jet cuttingmachine.

Similar numbers refer to similar parts throughout the drawings.

DETAILED DESCRIPTION

As shown in FIG. 1, the present invention pertains to a system andmethod for wireless control, a first embodiment thereof hereinafterreferred to as system 1. System 1 is adapted to provide control of anoperating device having at least one operation, which may be embodied ina device such as a water jet cutting machine, hereinafter referred to aswater jet cutting machine 2. System 1 provides control by way of acomputing device, hereinafter referred to as a remote control 4.

Water jet cutting machine 2 may be of any type of water jet device. Forthe present example, water jet cutting machine 2 is generally dividedinto a working unit 3 and a pump unit 5 interconnected by variouscomponents necessary and commonly used in the field of water jettechnology, for example, a line for high pressure water, electricalpower, and related mechanical elements and circuitry. Water jet cuttingmachine 2 further includes a control system or control unit 7 forcontrolling all of the various features of water jet cutting machine 2,including movement of water jet cutting machine 2 itself as well ascontrol of the internal mechanisms relating to the stream of highpressure water. Control unit 7 may be integrated with water jet cuttingmachine 2 or may be separately connected thereto by way of connectors,as discussed in greater detail below.

Pump unit 5 includes all of the various features and mechanisms formoving water jet cutting machine 2 within the desired environment,including movement such as forward, reverse, left, right, stop, jog,etc. Pump unit 5 further includes all of the various features andmechanisms for pumping high pressure water from a water reservoir (notshown) or hose (not shown) to working unit 3 for use thereby. Pump unit5 may further include a plurality of wheels 9 for use in moving waterjet cutting machine 2 within the desired environment. It will be readilyunderstood that pump unit 5 includes the various mechanical andelectrical components necessary for moving water jet cutting machine 2and supplying pumped high pressure water from pump unit 5 to workingunit 3.

Working unit 3 includes various components necessary for applying a highpressure stream of water to the desired environment. As such, workingunit 3 may include a nozzle holder 11 connected to a nozzle 13 for usein expelling a pressurized stream of water 14. Nozzle holder 11 andnozzle 13 are necessarily interconnected to the high pressure pumpedwater received from pump unit 5 as well as various motors or hydraulicmechanisms for moving nozzle 13 in the desired direction to expel highpressure stream of water 14 at a proper angle and flow rate in thedesired environment.

Control unit 7 is interconnected with a wireless module 15. Thisconnection may be done by a user manually coupling wireless module 15 tocontrol unit 7 in an aftermarket hardware upgrade, or wireless module 15may be integrated with control unit 7 by the manufacturer. Wirelessmodule 15 includes all of the various circuitry and components necessaryfor transmitting and receiving electromagnetic radiation, particularlyelectromagnetic radiation in the radio frequency spectrum, namely 3 kHzto 300 GHz. Henceforth, this electromagnetic radiation will be referredto as “signals”. Wireless signals received by wireless module 15 areused by control unit 7 to actuate the various components of water jetcutting machine 2. As such, wireless signals may actuate any of thevarious features or operations included in working unit 3 or pump unit5. These features or operations include moving water jet cutting machine2 in any direction or starting and stopping movement. The signals mayalso actuate any of the features or operations associated with nozzle 13such as starting or stopping the flow of water, narrowing or wideningthe flow of water, or raising or lowering nozzle 13. The signals mayalso initiate an emergency stop procedure wherein all of the componentsof water jet cutting machine 2 immediately stop or shut down, includingceasing pressurized stream of water 14. This emergency stop may dump orcease pressure at working unit 3 or pump unit 5, or may dump or ceasepressure at both working unit 3 and pump unit 5 to ensure safety and animmediate halt to the dangerous activity.

Control unit 7 may provide feedback relating to water jet cuttingmachine 2 to remote control 4 by way of wireless module 15. Control unit7 may gather and update internal metrics and system information andprovide this information to remote control 4 by way of wireless signalstransmitted by wireless module 15. Wireless module 15 may transmitinformation such as current pounds per square inch (“PSI”) ofpressurized stream of water 14, gallons per minute (“GPM”) ofpressurized stream of water 14, orifice size of nozzle 13, currentbattery charge of an onboard battery system (not shown), or any othermetrics or information available in water jet cutting machine 2. Controlunit 7 may also include a memory (not shown) which stores or logsinformation relating to the operation of water jet cutting machine 2 forlater transmission to remote control 4 or for later retrieval via anelectronic wired connection directly to control unit 7 or for sendingvia email or any other data retrieval means.

Remote control 4 includes a housing 19 formed and sized to be portableand easily carried by an individual user. Remote control 4 furtherincludes an interface 21 and wireless module 23 connected therebetweenby circuitry and supported by a processor and all of the variouselectronic and mechanical devices necessary to support a portablecomputing device. Interface 21 is preferably embodied in a touchscreeninterface. However, interface 21 may be any style of input/output systemwhich may receive and provide graphical or tactile or any otherinformational responses via an engagement with the user. Wireless module23 is similar to wireless module 15 in that wireless module 23 receivesand transmits signals by way of electromagnetic radiation in the radiofrequency spectrum. Wireless module 23 receives input from either theuser via interface 21 or from wireless module 15 via signals. In theevent that wireless module 23 receives input from the user via interface21, wireless module 23 translates this input into signals readable bywireless module 15 and transmits these signals wirelessly thereto.Alternatively, in the event that wireless module 23 receives input fromwireless module 15 via wireless signals, wireless module 23 translatesthis input into graphical or tactile representations and provides thisinput to the user via interface 21. Thus, it is a primary feature of thepresent invention to couple wireless module 23 with wireless module 15to enable a user to hold remote control 4 and wirelessly actuate thevarious components and systems of water jet cutting machine 2, includingany actuating any operations of machine 2.

Remote control 4 may be embodied by a common off-the-shelf componentsuch as a tablet, phone, or any other common mobile computing deviceavailable to a common consumer. This mobile computing device receives abundle of software or application which provides interface 21 to theuser via the interface of the computing device. As such, the user orbusiness may already own a device which can provide the hardwarerequired for remote control 4 for water jet system 1. This representsand enormous cost savings to the user as a critical underlying piece ofhardware for implementing system 1 may already be owned by the user.

As shown in FIG. 2, interface 21 includes at least two zones for use incontrolling and actuating the operations of water jet cutting machine 2.A control zone 25 is defined by interface 21 and used to display andinput information relating to the control of water jet cutting machine2. Control zone 25 may display the gathered metrics, feedback, or otherinformation captured by control unit 7 and transmitted to remote control4 by wireless module 15. Control zone 25 may also display a graphicaluser interface for controlling the movement of water jet cutting machine2, the water pressure, nozzle 13 orifice size, or any other feature oroperation the user may wish to control.

As shown in FIG. 2, a safety zone 27 is also defined by interface 21 andpreferably located proximate control zone 25. Safety zone 27 ispreferably touch sensitive and is connected via the circuitry and systemlogic of interface 21 to control unit 7 by way of wireless module 23 andwireless module 15. Safety zone 27 provides an elongated area along theside of interface 21 for receiving a finger of the user to ensure theuser is in control of remote control 4 and manually holding remotecontrol 4 by at least one hand. As such, safety zone 27 acts as a “deadman's switch” and is wired into the circuitry of interface 21 toimmediately and automatically stop dangerous operations of water jetcutting machine 2 in the event the user holding remote control 4manually releases a finger from safety zone 27.

Safety zone 27 and the ability to shut down system 1 in the event theuser is no longer in control represents a critical safety feature of thepresent invention in that any time a user releases the touch connectionbetween the user and safety zone 27, the dangerous operation of waterjet cutting machine 2 ceases. A user may release remote control 4 due toincapacitation, disability, simple neglect, or even due to recklessness.In the preferred embodiment of the invention, all operations of waterjet cutting machine 2 immediately stop when interface 21 senses arelease of a finger from safety zone 27. However, inasmuch as the mostcritical and dangerous component of water jet cutting machine 2 ispressurized stream of water 14, at the minimum, water jet system 1preferably ceases the operation of expelling pressured stream of water14 when safety zone 27 is released by the user.

The present invention may include the feature that the emergency “STOP”instruction generated by the release of the user's finger from safetyzone 27 is given top software level and machine level priority in waterjet system 1. In the underlying machine language, various interrupts andmessage priorities may be given to the instruction which informs controlunit 7 to cease operations of water jet cutting machine 2. This providesalmost instantaneous and real-time control of water jet cutting machine2 and ensures that the overall deactivation of water jet 2 is given toppriority at the software and machine level.

In as much as the user must be pressing at least one finger againstsafety zone 27, interface 21 continuously polls safety zone 27 for atouch input. When interface 21 receives an affirmative response that theuser is touching safety zone 27, interface 21 continues normaloperations and receives/transmits signals via wireless module 23 andinterface 21 as needed. Control zone 25 receives input from the user andoperates water jet cutting machine 2 as discussed above. However, thewireless nature of remote control 4 allows the user to adjust hisphysical whereabouts to best view and operate water jet cutting machine2 as long as safety zone 27 is receiving a touch from the user. As such,water jet system 1 provides additional safety benefits in that a user isnot “tied” to water jet cutting machine 2 by hoses or wires. The usermay move and adjust physical position accordingly to remain safe and tomore clearly observe the operations.

While the dead man's switch feature may be implemented by way of safetyzone 27 on touchscreen interface 21, the present invention may encompassany way of providing a similar safety feature for stopping an operationwhen system 1 senses the user is no longer in control. For example, abutton (not shown) may be provided which requires the user to push in orhold down the button to indicate the user is in control of system 1.Alternatively, a still camera or video camera (not shown) may beprovided to acquire images of the user or holder of a portion of system1 to indicate the user is in control of system 1. The camera may acquirean image and then determine if the image contains the user or is devoidof the user to determine if the user is in control of system 1. A lightsensor may be provided whereby the user must keep a thumb or finger overthe light sensor to indicate the user is in control of system 1. Agyroscopic sensor may be provided which senses movement in any of theX-axis, Y-axis, or Z-axis and uses this movement information todetermine whether the user is in control of system 1. Thus, the conceptof sensing whether a user is in control and thereafter enabling ordisabling an operation is a feature of the present invention. This maybe implemented with an element adapted to be actuated by a user, whereinthe actuation enables the operation and the absence of actuationdisables the operation. This may also be implemented with a switchvariable in an application installed on remote control 4 and logicallyconnected to an element, which determines which state the variable isset to. The switch variable may be set to a first state or a secondstate, whereby the first state indicates the application of remotecontrol 4 should enable the operation, and whereby the second stateindicates the operation should be disabled. The element logicallyconnected to the variable may be one of the aforementioned graphics on atouchscreen, button, camera, light sensor, or gyroscopic sensor, whichsets the switch variable based on whether the user is physicallyinteracting with system 1 to indicate the user is in control of system1.

Wireless module 15 and wireless module 23 are preferably wirelesslycoupled via Bluetooth technology. The Bluetooth protocol includes anumber of features which are advantageous to the present invention overalternative wireless communication systems. For example, Bluetoothrequires very little power per transmission signal, typically in the 1milliwatt range, so water jet cutting machine 2 and/or control unit 7may incorporate a battery to provide overall power to water jet cuttingmachine 2. This greatly improves mobility of water jet cutting machine2. This further increases safety, as an elongated hydraulic hose,pneumatic hose, or power line and the corresponding risk of accidentalcutting of said hose or power line may be eliminated from water jetcutting machine 2. Bluetooth further provides an inherent securityfeature in that the low power of the signals limits the distance betweenwater jet cutting machine 2 and remote control 4 to about ten meters.This limited range forces a user to actively remain in proximity towater jet cutting machine 2 while in use. One of the features of thepresent invention relates to the constant pinging back and forth betweenwireless module 15 and wireless module 23 to ensure the modules are inproximity. When a ping is unreturned, system 1 actuates a subroutine toshut down water jet cutting machine 2 to ensure safety. Further,Bluetooth technology does not require a line of sight between water jetcutting machine 2 and remote control 4 which is typically required inother wireless technologies such as infrared wireless communication.This allows a user to control water jet cutting machine 2 from a vehicleor behind a partition or safety shield. Finally, Bluetooth technologyuses spread-spectrum frequency hopping to ensure that no other devicesare transmitting on the same frequency at the same time. This provides acritical safety feature to ensure that no other devices can take controlof or affect water jet cutting machine 2 and/or control unit 7.

The wireless control of water jet cutting machine 2 by way of remotecontrol 4 may be provided by way of a modularized system which isconnectable to other operating devices such as water jet equipment andsystems, as represented by a generic water jet equipment 29 shown inFIGS. 5 and 6. Generic equipment 29 is representative of any water jetdevice which may be movable along a track, movable without a track, astationary device, any other style of operating device commonly found inany field. As shown in FIG. 3, one familiar with the water jet fieldwill recognize that control unit 7 discussed above with respect to waterjet cutting machine 2 improves elements commonly embodied in the priorart as an on board hardwired control system 30 and a control station 31.Onboard hardwired control system 30 is commonly connected via a group ofhydraulic, pneumatic, and/or electric hoses/wires 33 (henceforth knownas “lines 33”) to a set of sockets or connectors 32 of control station31. Control station 31 is actuated by a user 35 to send controllingpressure or electric signals via lines 33 to onboard control system 30,which in turn actuates equipment 29. User 35 manually manipulates aseries of mechanical controls 37 to actuate equipment 29. As discussedabove, this requires user 35 to stand in a fixed position to operateequipment 29. Further, control systems implementing control station 31such as those shown in FIGS. 3 and 5 do not incorporate any mechanism tosense whether user 35 has become incapacitated or moved away fromcontrol station 31.

As shown in FIG. 3-6, a second embodiment of the present invention isshown as system 101, which includes a portable control unit 131 incommunication with remote control 4. Portable control unit 131 includesa wireless module 115, similar to the previously discussed wirelessmodule 15 of water jet system 1. Portable control unit 131 furtherincludes a set of connectors 132, similar to connectors 32 of controlstation 31. In system 101, control unit 131 is connected to equipment 29in place of control station 31. An operator or user such as user 35operating system 101 manually locates control unit 131 in closeproximity to equipment 29. User 35 then manually disconnects lines 33from connectors 32 of control station 31 and reconnects those lines 33to the appropriate connectors 132 of control unit 131. User 35 theninitiates a Bluetooth pairing of control unit 131 with remote control 4via wireless module 115 of control unit 131 and wireless module 23 ofremote control 4. Once control unit 131 is paired and coupled withremote control 4, user 35 simply manipulates interface 21 while holdinga finger on safety zone 27 to operate equipment 29. User 35 is free tomove about to more easily see the operation of equipment 29 or to moveto safer areas as equipment 29 performs its operations.

In as much as the water jet industry enjoys a generally standardized setof connectors for actuating various equipment or machines, control unit131 can be connected to a number of different pieces of equipment toprovide wireless control and a dead man's switch to any user of thatequipment. Further, adapters may be provided to interconnect anynecessary items or elements and to allow control unit 131 to connectwith various equipment and operating devices. Further, control unit 131is entirely portable and able to be easily transported between jobsitesby a single individual with no specialized equipment. This represents anadvantage over the prior art which provided large bulky control unitssuch as those indicated as control station 31 in FIGS. 3 and 5. As shownin FIG. 3, one will readily note the size and weight differences betweencontrol station 31 and control unit 131. The small size and portabilityof control unit 131 allows a user to transport wireless control system101 between physical locations. Further, efficiencies are realized byusing one control unit 131 in place of several control stations 31. Asshown in FIG. 4, control unit 131 may be provided with a handle 175extending from a housing 176 used to encapsulate the internal mechanismsof control unit 131. Control unit 131 is further provided with anelectrical input such as a power receiving prong or set of prongs (notshown) for receiving a power cord from an electrical source. Further,control unit 131 may be provided with a battery backup system (notshown) for providing batter power to control unit 131 in the event of apower outage or simply to provide better portability to control unit131.

Control unit 131 is provided with various mechanical components foractuating the various connectors 132 as instructed by the holder ofremote control 4. A set of solenoids (not shown) may be used to turn aparticular connector on or off. The set of solenoids may beelectronically actuated, hydraulically actuated, or pneumaticallyactuated. Further, it has been discovered that the bleed off pilotpressure from a particular electronically actuated solenoid may beconnected with a manual hydraulic or manual pneumatic actuation controlto allow a user to manually actuate the electronic solenoid in the eventof a power failure. This manual actuation may then be actuated by a userto stop a process when the electric power to the solenoid is notoperating and provides a critical safety mechanism for control unit 131.While solenoids may be used for on/off control of connectors 132, asimilar set of servomotors (not shown) may be used in conjunction withthe set of solenoids to control the rate of flow through the connectors.

Control unit 131 may include one or more sensors for ensuring overallsafety in system 1. Control unit 131 may include a gyroscopic sensor(not shown) which actuates system 1 to initiate a subroutine to shutdown equipment 29 when it senses any kind of quick movement of controlunit 131. The movement may be caused by an accident on the job site, anearthquake, an explosion, a vehicle bumping or disrupting control unit131 or any other reason for unintentionally imparting quick movement tocontrol unit 131. This safety feature allows for an automatic deadmanswitch type of shut down of equipment 29. Other sensors may also beemployed for similar safety and automatic shutdown of equipment 29. Forexample, a pressure sensor may be employed for use in shutting downequipment 29 in the event of a drop or rise in pressure beyond apredetermined threshold. Likewise, a gas sensor for detecting flammablegases may be employed in a similar manner. Further, a battery sensor orsubroutine may be employed to track the battery life of remote control 4and to ensure equipment 29 is automatically shutdown before remotecontrol 4 loses power.

While equipment in the field all includes a generally standardized setof connectors, the actual pressures, voltages, hydraulics, etc. used tointeract with the equipment needs tailored or customized for each modelof equipment, each equipment family, or each operating device. This isaddressed by offering plugins, software updates, or even entirelydifferent encapsulated applications for each model of equipment orequipment family which a user may desire to control. As such, interface21 may be offered in whole or in part as a physical bundle of software,a software download from the Internet, or as a precompiled applicationdownloadable through an application store such as iTunes® or Google AppsMarketplace®, or downloadable through the Internet in general. One willreadily understand that this software may be offered for each desiredunderlying operating system or hardware architecture to allow a user touse an off-the-shelf tablet or mobile device as remote control 4.

For example, if a user purchases or rents a particular piece ofequipment 29A and desires to utilize system 101 with equipment 29A, theuser downloads and installs software which is tailored to provide aninterface 21A on the user's mobile device. This enables that device tobecome remote control 4 and control equipment 29A. If the user has aniPad®, the software download will be compiled and customized to run onan iPad®. If that user wishes to use a new piece of equipment 29B,system 101 may include the feature that the user may update the softwareto provide an interface 29B to control equipment 29B. System 101 mayalternatively include the feature that the user may download a new pieceof software which is tailored to provide interface 29B on the user'smobile device. Or the software may be configured such that a user mustpurchase a new activation code to use interface 21 with a new piece ofequipment.

Similar to updating or changing the underlying software, the hardwaremay be updated or changed as well in system 101. If the user acquires aKindle Fire® and wishes to now control equipment 29B on the Kindle Fire®the software to provide interface 29B may be downloaded and installed onthe Kindle Fire®. As such, any method for providing to the user a way toincorporate an off-the-shelf mobile device with interface 21 iscontemplated by the present invention. The underlying software toprovide interface 21 may be a single download, a plugin to previouslyinstalled software, or any other method common in the art for providingand updating software.

The application used with remote control 4 to control the operatingdevice may be configured or programmed to utilize one or more particularhardware features of the computing device, such as a touchscreen,button, camera, light sensor, or gyroscopic sensor. These pieces ofcomputing hardware may be logically connected to internal variablesresiding in the application and may be configured to control theenabling and disabling of an operation on the operating device.

Interface 21 and the software involved with providing interface 21 maykeep a detailed record of events and status information produced whileinterface 21 is used. Further, system 101 may provide a data collectionsubroutine running in the background to export all data or any relevantdata to a file or database for later analytics or review. System 101 mayeven store commonly used routines or manipulations of interface 21 forrepeatability of common operations. Costing and timing information maybe obtained and stored by the software. Interface 21 may be integratedwith accounting or purchasing software, or automatically update adatabase such as an enterprise level inventory database, etc. Usage anddepreciation of particular system components such as a blade or a nozzlemay be automatically calculated and linked with a purchasing system. Allof these features are contemplated and within the scope of system 101.

While the above system 101 is discussed with respect to the water jetcutting field, it will be readily apparent that control unit 131 may bereconfigured and customized to apply to any field of commercial orindustrial activities. It follows that interface 21 may also becustomized to apply to the alternative field of commercial or industrialactivities. Thus, it is within the scope of the present invention that awireless control system similar to those discussed above may beconnected or coupled to any device where the user is required to betethered to or in a fixed position for operating the device or where adeadman switch would be beneficial.

In the foregoing description, certain terms have been used for brevity,clearness, and understanding. No unnecessary limitations are to beimplied therefrom beyond the requirement of the prior art because suchterms are used for descriptive purposes and are intended to be broadlyconstrued.

Moreover, the description and illustration of the preferred embodimentof the invention are an example and the invention is not limited to theexact details shown or described.

1. A system comprising: a computing device, wherein the computing deviceincludes a first wireless module; a machine that is pneumatically orhydraulically operable; a second wireless module, wherein the secondwireless module is connected to the machine; a wireless communicationslink between the computing device and the machine, wherein the wirelesscommunication link is formed by the first wireless module and the secondwireless module; a signal, wherein the signal is generated by thecomputing device and communicated to the machine by way of the wirelesscommunications link; and wherein the machine is actuated the signal isreceived.
 2. The system as defined in claim 1, wherein the machineincludes a pump and the pump is actuated when the machine receives thesignal.
 3. The system as defined in claim 2, wherein the machine is afluid jet machine and the pump is operatively engaged with a nozzle; andwherein actuation of the pump causes fluid to flow under pressure fromthe nozzle.
 4. The system of claim 1, further comprising: a controlunit, wherein the second wireless module is disposed in the controlunit; and a connector, wherein the control unit is connected to themachine by the connector.
 5. The system of claim 2, further comprising:a control unit, wherein the second wireless module is disposed in thecontrol unit; a connector, wherein the control unit is connected to themachine by the connector; a valve disposed in the control unit andoperable in an open position and a closed position; wherein the controlunit is in communication with the machine when the valve is in the openposition; and wherein the pump is actuated when the control unit is incommunication with the machine.
 6. The system of claim 5, wherein thesignal is communicated to the control unit by way of the wirelesscommunication link, and wherein the valve moves to the open positionwhen the control unit receives the signal.
 7. The system of claim 1,wherein the wireless communications link is formed using Bluetoothwireless communications protocol.
 8. The system of claim 1, furthercomprising a touchscreen interface on the computing device.
 9. Thesystem of claim 1, further comprising: a display on the computingdevice; a set of system metrics, wherein the set of system metrics iscommunicated from the machine to the computing device by way of thewireless communications link; and an output presented on the display,wherein the output graphically represents the set of system metrics. 10.A method comprising the steps of: forming a wireless communication linkbetween a portable computing device and a machine that is hydraulicallyor pneumatically operable; sending a first signal from the computingdevice to the machine via the wireless communication link; and actuatingthe machine upon receiving the first signal.
 11. The method of claim 10,further comprising the steps of: connecting a first wireless module to asecond wireless module to form the wireless communication linktherebetween, wherein the first wireless module is disposed in thecomputing device, and wherein the second wireless module is connected tothe machine.
 12. The method of claim 11, further comprising: forming thewireless communication link with a Bluetooth communication protocol. 13.The method of claim 10, further comprising the steps of: sending asecond signal from the machine to the computing device via the wirelesscommunications link; and updating a display on the computing device uponreceiving the second signal.
 14. The method of claim 10, furthercomprising the steps of: actuating an element on the computing deviceprior to the step of sending the first signal; sending a terminationsignal from the computing device to the machine when the element is nolonger actuated; and halting operation of the machine when the machinereceives the termination signal.
 15. The method of claim 10, wherein themachine is a fluid jet machine and includes a pump and nozzle; andwherein the step of actuating the machine includes actuating the pumpand causing a pressurized jet of fluid to flow from the nozzle.
 16. Themethod of claim 10, wherein the machine includes wheels and the step ofactuating the machine includes actuating the wheels and physicallymoving the machine over a surface.
 17. A method comprising the steps of:forming a wireless communication link between a portable computingdevice and a control unit; forming a wired communication link betweenthe control unit and a machine; sending a first signal from thecomputing device to the control unit via the wireless communicationlink; translating the first signal into a second signal; sending thesecond signal from the control unit to the machine via the wiredcommunications link; and actuating an operation of the machine uponreceiving the second signal.
 18. The method of claim 17, wherein thestep of actuating an operation of the machine includes actuating ahydraulic system or a pneumatic system of the machine.
 19. The method ofclaim 17, further comprising the steps of: connecting a first wirelessmodule to a second wireless module to form the wireless communicationlink therebetween, wherein the first wireless module is disposed in thecomputing device, and wherein the second wireless module is disposed inthe control unit.
 20. The method of claim 19, further comprising thesteps of: sending a third signal from the machine to the control unitvia the wired communications link; translating the third signal to afourth signal; sending the fourth signal from the control unit to thecomputing device via the wireless communications link; and updating adisplay on the computing device upon receiving the fourth signal.